• 한국결정성장학회지
• /
• 제7권3호
• /
• pp.418-427
• /
• 1997

$La_2O_3$가 각각 0, 0.1, 0.3, 0.5, 0.7, 1, 3, 5 mole% 첨가된 $0.05pb(Sn_{0.5}Sb_{0.5})O_3＋0.11PbTiO_30.84PbZroO_3＋0.4Wt%MnO_2$ (이하 0.05PSS -0.11PT-0.84PZ+0.4wt%$MnO_2$)계를, $1250^{\circ}C$에서 $PbZrO_3$를 분위기 분말로 사용하여 성형체 무게의 1/2을 함께 넣고 소결체를 제조하여 그 특성을 분석하였다. 소결체의 밀도는 7.683 g/$\textrm {cm}^3$에서 7.515 g/$\textrm {cm}^3$ 범위였으며, 3 mole% $La_2O_3$를 첨가한 경우 가장 높은 값을 나타내었다. 0에서 5 mole% 범위에서 $La_2O_3$ 첨가량을 증가시킬 때 평균 입경이 9.0 $\mu \textrm{m}$에서 1.3 $\mu\textrm{m}$까지 감소되었다. 결정구조의 경우 $La_2O_3$첨가량을 0에서 1 mole%로 할 때 0.05PSS-0.11 PT-0,84PZ계에서 고용된 상을 형성하였으나 3, 5 mole%로 첨가량을 증가시킴에 따라 제2차 산이 형성되었고, 소결체를 $120^{\circ}C$ 또는 $140^{\circ}C$에서 $5 KV_{DC}$ /mm로 20분간 poling 전후에 $La_2O_3$ 첨가량이 0 에서 3 mlole%까지 증가될수록 1KHz에서의 유전 상수는 증가되었으며, 유전손실은 모든 경우에서 1 % 미만의 값을 나타내었다. $La_2$O$_3$첨가량이 0, 0.5, 1, 3 mole%로 증가됨에 따라 큐리온도가 208$^{\circ}C$, 183$^{\circ}C$, $152^{\circ}C$ 그리고 $127^{\circ}C$로 감소되었다. $La_2O_3$가 증가됨에 따라 대체로 $K_{p}$ 증가되었으며 0.7 mlole%의 $La_2O_3$를 첨가한 소결체를 $140^{\circ}C$에서 poling한 경우 가장 높은 $K_p$값으로 14.5 %를 나타내었다.

• Nuclear Engineering and Technology
• /
• 제38권2호
• /
• pp.163-174
• /
• 2006

The $Ph{\acute{e}}bus$ FP project is an international reactor safety project. Its main objective is to study the release, transport and retention of fission products in a severe accident of a light water reactor (LWR). The FPT4 test was performed with a fuel debris bed geometry, to look at late phase core degradation and the releases of low volatile fission products and actinides. Post Test Analyses results indicate that releases of noble gases (Xe, Kr) and high-volatile fission products (Cs, I) were nearly complete and comparable to those obtained during $Ph{\acute{e}}bus$ tests performed with a fuel bundle geometry (FPT1, FPT2). Volatile fission products such as Mo, Te, Rb, Sb were released significantly as in previous tests. Ba integral release was greater than that observed during FPT1. Release of Ru was comparable to that observed during FPT1 and FPT2. As in other $Ph{\acute{e}}bus$ tests, the Ru distribution suggests Ru volatilization followed by fast redeposition in the fuelled section. The similar release fraction for all lanthanides and fuel elements suggests the released fuel particles deposited onto the plenum surfaces. A blockage by molten material induced a steam by-pass which may explain some of the low releases. The revaporisation testing under different atmospheres (pure steam, $H_2/N_2$ and steam /$H_2$) and up to $1000^{\circ}C$ was performed on samples from the first upper plenum. These showed high releases of Cs for all the atmospheres tested. However, different kinetics of revaporisation were observed depending on the gas composition and temperature. Besides Cs, significant revaporisations of other elements were observed: e.g. Ag under reducing conditions, Cd and Sn in steam-containing atmospheres. Revaporisation of small amounts of fuel was also observed in pure steam atmosphere.

• 자원환경지질
• /
• 제29권4호
• /
• pp.411-419
• /
• 1996

The Janggun magnetite deposits occur as the lens-shaped magnesian skarn, magnetite and base-metal sulfide orebodies developed in the Cambrian Janggun Limestone Formation. The K-Ar age of alteration sericite indicates that the mineralization took place during late Cretaceous age (107 to 70 Ma). The ore deposition is divided into two stages as a early skarn and late hydrothermal stage. Mineralogy of skara stage (107 Ma) consists of iron oxide, base-metal sulfides, Mg-Fe carbonates and some Mg- and Ca-skarn minerals, and those of the hydrothermal stage (70 Ma) is deposited base-metal sulfides, some Sb- and Sn-sulfosalts, and native bismuth. Based on mineral assemblages, chemical compositions and thermodynamic considerations, the formation temperature, $-logfs_2$, $-logfo_2$ and pH of ore fluids progressively decreased and/or increased with time from skarn stage (433 to $345^{\circ}C$, 8.8 to 9.9 atm, 29.4 to 31.6 atm, and 6.1 to 7.2) to hydrothermal stage (245 to $315^{\circ}C$, 11.2 to 12.3 atm, 33.6 to 35.4 atm, and 7.3 to 7.8). The ${\delta}^{34}S$ values of sulfides have a wide range between 3.2 to 11.6‰. The calculated ${\delta}^{34}S_{H_2S}$ values of ore fluids are relatively homo-geneous as 2.9 to 5.4‰ (skam stage) and 8.7 to 13.5‰ (hydrothermal stage), which are a deep-seated igneous source of sulfur indicates progressive increasing due to the mixing of oxidized sedimentary sulfur with increasing paragenetic time. The ${\delta}^{13}C$ values of carbonates in ores range from -4.6 to -2.5‰. Oxygen and hydrogen isotope data revealed that the ${\delta}^{38}O_{H_2O}$ and ${\delta}D$ values of ore fluids decreased gradually with time from 14.7 to 1.8‰ and -85 to -73‰ (skarn stage), and from 11.1 to -0.2‰ and -87 to -80‰ (hydrothermal stage), respectively. This indicates that magmatic water was dominant during the early skarn mineralization but was progressively replaced by meteoric water during the later hydrothermal replacement.

• 한국환경보건학회지
• /
• 제49권2호
• /
• pp.66-77
• /
• 2023

Background: Along with the increase in consumer interest in and consumption of tattoo products, the controversy over harmful heavy metals associated with the use of tattoo cosmetics is also increasing. Therefore, investigation of hazardous metals in these tattoo products is needed. Objectives: This study was performed to provide useful data for establishing reasonable standards to securely manage tattoo cosmetics, tattoo stickers, and tattoo inks distributed in the market. Methods: Thirteen kinds of hazardous metal contents (Pb, As, Cd, Sb, Ni, Co, Cu, Cr, Se, Ba, Zn, Sn, and Hg) were analyzed for 23 tattoo cosmetics, ten tattoo stickers, and 16 tattoo inks. Hg was measured through the combustion-gold amalgamation method, and other hazardous metals were measured by inductively coupled plasma-mass spectrometry (ICP-MS) after acidic decomposition using a microwave apparatus. Results: The detected ranges of Pb, As, Cd, Sb, Ni, and Hg in tattoo cosmetics were 0.07~1.18, 0.06~0.41, ND~0.07, 0.01~3.44, 0.12~2.75, and ND~0.01 ㎍/g, respectively. All of the hazardous metals detected were below the recommended maximum standards of the Ministry of Food and Drug Safety. The mean amount of Pb detected in tattoo stickers for children was 0.24 ㎍/kg and Cd was not detected, meaning both metals met the recommended criteria. There was no statistically significant difference in all measured metals between children's tattoo stickers and adults' tattoo stickers. In the results of the study on the hazardous metal content of tattoo inks, four products (25%) for Pb, one product (6%) for As, 13 products (81%) for Ni, four products (25%) for Cu, and five products (31%) for Zn exceeded the recommended standards approved by the government. The highest predicted exposure amount for hazardous metals exceeding the recommended level of tattoo inks in a single tattooing was 5.69 ㎍/kg for Ni, 8.51 ㎍/kg for Zn, 0.44 ㎍/kg for Pb, 8.07 ㎍/kg for Cu, 0.44 ㎍/kg for As, and 71.36 ㎍/kg for Ba. Conclusions: It is necessary to prepare criteria for content limitation for the management of Co, Cr, Ba and Se tattoo cosmetics, and tattoo inks require thorough quality control.